A turbine housing assembly includes a plurality of constituent members connected to one another and easily manufactured. The turbine housing assembly includes a scroll part, an annular lid part, an exhaust gas outlet and a connection part connectable to a bearing housing for a turbine shaft. The scroll part and the connection part are each formed of a single piece of sheet metal and each is welded to the annular lid part that is orthogonal to a turbine axial direction so that the scroll part and the connection part are connected to each other via the annular lid part. Such a turbine housing assembly is of reduced weight, is quite easy to manufacture, of reduced cost, and can be made, at least in part, of materials having lower heat capacity as compared to conventional turbine housings made of sheet metal.
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1. A turbine housing assembly including a plurality of constituent members connected to one another to constitute a turbine housing into which a turbine wheel rotated by exhaust gas introduced from an engine is inserted, the turbine housing assembly at least comprising:
a scroll part made of sheet metal having a bottomed cylindrical shape, a surrounding wall part and a bottom face part, the scroll part including:
an exhaust gas flow path of a spiral shape formed inside the bottomed cylindrical shape and configured such that exhaust gas that has flowed in from an exhaust gas inlet flows through the exhaust gas flow path; and
an exhaust gas outlet having a through hole formed on the bottom face part, the exhaust gas outlet being configured such that the exhaust gas that has flowed through the exhaust gas flow path flows out from the exhaust gas outlet;
a connection part made of sheet metal and connectable to a bearing housing that houses a bearing for supporting a rotation shaft of the turbine wheel, said connection part comprising bushing holes,
an annular lid part orthogonal to a turbine axial direction, the scroll part being welded to one surface of the annular lid part and the connection part being welded to the other surface of the annular lid part, wherein
the annular lid part includes a flat plate-like part of an annular shape and a positioning portion protruding outwardly from the flat plate-like part, and
an end face of a threaded bushing is inserted into a bushing insertion hole formed on the connection part and connected to the positioning portion of the annular lid part.
8. A manufacturing method for a turbine housing assembly including a plurality of constituent members connected to one another to constitute a turbine housing into which a turbine wheel rotated by exhaust gas introduced from an engine is inserted, the manufacturing method comprising:
forming a scroll part of a single piece of sheet metal, the scroll part having:
a bottomed cylindrical shape including a surrounding wall part and a bottom face part;
an exhaust gas flow path of a spiral shape formed inside the bottomed cylindrical shape, the exhaust gas flow path being configured such that exhaust gas that has flowed in from an exhaust gas inlet flows through the exhaust gas flow path; and
an exhaust gas outlet having a through hole formed on the bottom face part, the exhaust gas outlet being configured such that the exhaust gas that has flowed through the exhaust gas flow path flows out from the exhaust gas outlet;
forming a connection part of a single piece of sheet metal, the connection part being connectable to a bearing housing that houses a bearing for supporting a rotation shaft of the turbine wheel, said connection part comprising bushing insertion holes;
forming an annular lid part of a flat plate-like annular shape of a single piece of sheet metal, the annular lid part including a flat plate-like part of an annular shape and a positioning portion protruding outwardly from the flat plate-like part; and
arranging the annular lid part to be orthogonal to a turbine axial direction, welding the scroll part to one side of the annular lid part, and welding the connection part to other side of the annular lid part, wherein
said method further comprising inserting an end face of a threaded bushing into a bushing insertion hole formed on the connection part and connecting the connecting part to the positioning portion of the annular lid part.
2. The turbine housing assembly according to
3. The turbine housing assembly according to
4. The turbine housing assembly according to
5. The turbine housing assembly according to
6. The turbine housing assembly according to
7. The turbine housing assembly according to
9. The manufacturing method for a turbine housing assembly according to
preparing an exhaust part of a tubular shape comprising a separate body separate from the scroll part, and connecting the exhaust part to the scroll part in the turbine axial direction so that the exhaust part is in communication with the exhaust gas outlet of the scroll part.
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The present invention relates to a turbine housing assembly which includes a plurality of constituent members connected to one another to constitute a turbine housing into which a turbine wheel rotated by exhaust gas introduced from an engine may be inserted, and a manufacturing method of the turbine housing assembly.
Conventionally, there has been known a turbocharger in which a turbine wheel is rotated by utilizing energy of exhaust gas introduced from an engine to rotate a compressor wheel disposed coaxially with the turbine wheel, so that pressurized air is supplied to an air-intake manifold, thereby improving output of the engine. In recent years, in the case where such a turbocharger is to be mounted on a vehicle, there is need for reduction of weight, cost-cutting, facilitation of manufacture, reduction of heat capacity, or the like. Thus, a turbine housing made of sheet metal has been increasingly used in the place of a conventional turbine housing made by casting.
As an example of a turbine housing made of sheet metal, Patent Document 1 discloses a turbine housing which includes a scroll part formed by bringing two right-and-left sheet metal members each having a plate-like shape or a bowl-like shape in contact with each other, and welding them in the circumferential direction, the scroll part having an exhaust gas flow path of a spiral shape formed inside. In addition, Patent Document 2 discloses a turbine housing including a housing of a scroll-like shape made of sheet metal and having an exhaust gas flow path of a spiral shape formed therein and an outer shell made of sheet metal, the outer shell being configured to cover the housing of a scroll-like shape.
However, for the above described turbine housing of Patent Document 1, the manufacture of the scroll part requires troublesome steps because the scroll part is formed by preparing two right-and-left sheet metal members each having a complex shape processed into a plate-like shape or a bowl-like shape, bringing the two members into contact with each other, and welding them in the circumferential direction. Further, although Patent Document 1 discloses that the scroll part made of sheet metal is directly connected to a bearing housing made by casting (
Furthermore, the above described turbine housing of Patent Document 2 includes a housing, a bearing ring or the like fitted with one another, which negatively affects sealability of the housing with respect to exhaust gas. Thus, for the turbine housing of Patent Document 2, it is necessary to provide an outer shell for covering the housing of a scroll-like shape, which raises a problem in that it is difficult to reduce the weight and heat capacity of the turbine housing sufficiently.
The present invention was made in view of the above described problem of the prior art. An object is to provide a turbine housing assembly in which reduction of weight, facilitation of manufacture, cost-cutting, reduction of heat capacity are further promoted compared to a conventional turbine housing made of sheet metal, and a manufacturing method of the turbine housing assembly.
The present invention was made to achieve the above described object. A turbine housing assembly of the present invention includes a plurality of constituent members connected to one another to constitute a turbine housing into which a turbine wheel rotated by exhaust gas introduced from an engine is inserted. The turbine housing assembly at least includes: a scroll part of a bottomed cylindrical shape that has a surrounding wall part and a bottom face part, the scroll part including: an exhaust gas flow path of a spiral shape formed inside the bottomed cylindrical shape and configured such that exhaust gas that has flowed in from an exhaust gas inlet flows through the exhaust gas flow path; and an exhaust gas outlet having a through hole formed on the bottom face part, the exhaust gas outlet being configured such that the exhaust gas that has flowed through the exhaust gas flow path flows out from the exhaust gas outlet; and a connection part connectable to a bearing housing that houses a bearing for supporting a rotation shaft of the turbine wheel, the scroll part and the connection part each being formed by processing a single piece of sheet metal and each being welded to an annular lid part that is orthogonal to a turbine axial direction, so that the scroll part and the connection part are connected to each other in the turbine axial direction via the annular lid part.
For the turbine housing assembly of the above configuration, a turbine housing is broken down into modules such as the scroll part inside which the exhaust gas flow path of a spiral shape is formed and the connection part configured connectable to a bearing housing, the scroll part and the connection part each being formed by processing a single piece of sheet metal. Also, the scroll part and the connection part are each welded to the annular lid part that is orthogonal to the turbine axial direction, so as to be connected to each other in the turbine axial direction via the annular lid part.
Since a turbine housing is broken down into modules such as the scroll part and the connection part, the scroll part and the connection part each being formed by processing a single piece of sheet metal, it is possible to reduce the heat capacity and weight of the turbine hosing. Also, since the scroll part and the connection part are each formed by processing a single piece of sheet metal, the manufacture of the same is facilitated.
Further, since it is configured such that the turbine housing is broken down into modules such as the scroll part inside which the exhaust gas flow path of a spiral shape is formed and the connection part configured connectable to a bearing housing, the scroll part and the connection part being connected to each other via the annular lid part, it is possible to configure the turbine housing assembly of the present invention as an assembly of a plurality of standardized constituent modules, which makes it possible to facilitate the manufacture. Also, since the scroll part and the connection part are connected to each other by welding, the sealability is enhanced and thus a conventional outer shell is no longer required. As a result, it is possible to reduce the weight and heat capacity of the turbine housing.
Still further, since the turbine housing is broken down into modules such as the scroll part and the connection part, which are connected to each other in the turbine axial direction via the annular lid part that is orthogonal to the turbine axial direction, it is possible to block the influence of the exhaust gas having a high temperature in the scroll part by the annular lid part. Thus, it is possible to form the connection part of a material having lower heat resistance than that of the scroll part. That is, it is possible to form the connection part of a less expensive material containing less nickel than the scroll part. As a result, it is possible to reduce the cost.
Furthermore, in the above invention, with the annular lid part having a separate body separate from the scroll part and the connection part, it is possible to form each constituent member included in the turbine housing assembly of the present invention such as the scroll part, the connection part, and the annular lid part into a simple shape. As a result, it is possible to facilitate the manufacture of each constituent member.
Also at this time, in the above invention, forming the annular lid part by processing a single piece of sheet metal contributes to reducing the weight and heat capacity of the turbine housing as well.
Further, in the above invention, the turbine housing assembly further includes an exhaust part of a tubular shape having a separate body separate from the scroll part, and the exhaust part is connected to the scroll part in the turbine axial direction so as to communicate with the exhaust gas outlet.
As described above, by breaking down a turbine housing into modules such as the scroll part, the connection part, and the exhaust part of a tubular shape, and configuring the exhaust part of a tubular shape to have a separate body separate from the scroll part, it is possible to form each constituent member included in the turbine housing of the present invention into a simple shape, thereby facilitating the manufacture of each constituent member. Further, since the exhaust part is connected to the scroll part in the turbine axial direction, the constituent members included in the turbine housing assembly of the present invention such as the connection part, the annular lid part, the scroll part and the exhaust part are all connected in the turbine axial direction. As a result, assembling property of the turbine housing assembly is improved.
The turbine housing assembly of the present invention with the above configuration includes a variable nozzle mechanism that adjusts flow of the exhaust gas flowing into the turbine wheel, the variable nozzle mechanism being inserted into the scroll part and the connection part. In other words, the turbine housing assembly constitutes a turbine housing of a variable geometry turbocharger.
Further, a manufacturing method of the present invention is for a turbine housing assembly which includes a plurality of constituent members connected to one another to constitute a turbine housing into which a turbine wheel rotated by exhaust gas introduced from an engine is inserted. The manufacturing method includes: a scroll part forming step of forming a scroll part by processing a single piece of sheet metal, the scroll part having: a bottomed cylindrical shape including a surrounding wall part and a bottom face part; an exhaust gas flow path of a spiral shape formed inside the bottomed cylindrical shape, the exhaust gas flow path being configured such that exhaust gas that has flowed in from an exhaust gas inlet flows through the exhaust gas flow path; and an exhaust gas outlet having a through hole formed on the bottom face part, the exhaust gas outlet being configured such that the exhaust gas that has flowed through the exhaust gas flow path flows out from the exhaust gas outlet; and a connection part forming step of forming a connection part by processing a single piece of sheet metal, the connection part being connectable to a bearing housing that houses a bearing for supporting a rotation shaft of the turbine wheel; an annular lid part forming step of forming an annular lid part of a flat plate-like annular shape by processing a single piece of sheet metal; and a welding step of arranging the annular lid part to be orthogonal to a turbine axial direction, welding the scroll part to one side of the annular lid part, and welding the connection part to other side of the annular lid part.
For the manufacturing method for the turbine housing assembly 1 of the present invention configured as above, a turbine housing is broken down into modules such as the scroll part inside which the exhaust gas flow path of a spiral shape is formed and the connection part connectable to a bearing housing, and the scroll part and the connection part are each formed by processing a single piece of sheet metal. Then, the scroll part and the connection part are each welded to the annular lid part that is orthogonal to the turbine axial direction so as to be connected to each other in the turbine axial direction via the annular lid part. As a result, the turbine housing assembly is manufactured.
Since a turbine housing is broken down into modules such as the scroll part and the connection part and then the scroll part and the connection part are each formed by processing a single piece of sheet metal, it is possible to reduce the heat capacity and weight of the turbine housing. Also, since the scroll part and the connection part are each formed by processing a single piece of sheet metal, the manufacture of the same is facilitated.
Furthermore, since the annular lid part has a separate body separate from the scroll part and the connection part, it is possible to form each constituent member included in the turbine housing assembly of the present invention such as the scroll part, the connection part, and the annular lid part into a simple shape. As a result, it is possible to facilitate the manufacture of each constituent member.
Further, in the above invention, the exhaust part of a tubular shape having a separate body separate from the scroll part is prepared. Then, the connection step is included, where the exhaust part and the scroll part are connected to each other in the turbine axial direction so that the exhaust part communicates with the exhaust gas outlet of the scroll part. Thus, all of the constituent members included in the turbine housing assembly of the present invention such as the connection part, the annular lid part, the scroll part and the exhaust part are connected in the turbine axial direction. As a result, assembling property of the turbine housing assembly is improved.
According to the present invention, it is possible to provide a turbine housing assembly in which reduction of weight, facilitation of manufacture, cost-cutting, reduction of heat capacity are even more promoted compared to a conventional turbine housing made of sheet metal, and a manufacturing method of the turbine housing assembly.
Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It is intended, however, that unless particularly specified, dimensions, materials, shapes, relative positions and the like of components described in the embodiments shall be interpreted as illustrative only and not limitative of the scope of the present invention.
Although not particularly limited to this, a turbine housing assembly 1 of the present invention is a turbine housing of a VG (variable geometry) turbocharger including a variable nozzle mechanism, for instance. The VG turbocharger includes a variable nozzle mechanism in a turbine housing and controls the amount of exhaust gas flow to be introduced by adjusting the opening degree of the nozzles in the variable nozzle mechanism according to the conditions of the engine. Then, the VG turbocharger controls the supply pressure to the optimum pressure by increasing or decreasing the rotation speed of a turbine wheel by the amount of exhaust gas flow.
A turbine housing assembly 1 of the present invention is configured as illustrated in
As illustrated in
As illustrated in
Further, as illustrated in
Still further, as illustrated in
As illustrated in
As illustrated in
The scroll part 2, the connection part 4, and the annular lid part 6 are each formed by processing a single piece of sheet metal. That is, each of the above is formed by plastic-deforming a flat plate-like piece of sheet metal into a predetermined shape by processes such as bending and pressing, or by partially cutting-off unnecessary portions by processes such as punching. Further, as a material of the scroll part 2, connection part 4, and annular lid part 6, for instance, a heat-resistant steel such as austenite stainless steel may be suitably used.
As illustrated in
Still further, as illustrated in
In other words, as exhaust gas that has passed through the turbine wheel 5 expands so that its temperature decreases in the first place, the temperature of the exhaust gas flowing into the exhaust part 8 is lower than that of the exhaust gas flowing through the exhaust gas flow path 2A by approximately 100 degrees. Accordingly, with the exhaust part 8 and the scroll part 2 being connected so that the gap “a” is formed between the outer circumferential face of the exhaust part 8 and the projecting portion 22a, it becomes difficult for the exhaust gas having a high temperature and flowing through the exhaust gas flow path 2A to affect the exhaust part 8. Thus, it is possible to select a material of the exhaust part 8 in accordance with the temperature of the exhaust gas that passes through the exhaust part 8. As a result, it is possible to form the exhaust part 8 of a material having less heat resistance than that of the scroll part 2 (specifically, a stainless material that contains less nickel and is less expensive).
Further, as illustrated in
Here, as illustrated in
As described above, for the turbine housing assembly 1 of the present invention, a turbine housing is broken down into modules such as the scroll part 2 inside which the exhaust gas flow path 2A of a spiral shape is formed and the connection part 4 connectable to a bearing housing, and the scroll part 2 and the connection part 4 are each formed by processing a single piece of sheet metal. Further, the scroll part 2 and the connection part 4 are each welded to the annular lid part 6 that is orthogonal to the turbine axial direction line 7 so as to be connected to each other in the turbine axial direction via the annular lid part 6.
According to the turbine housing assembly 1 of the present invention configured as described above, since a turbine housing is broken down into modules such as the scroll part 2 and the connection part 4, each of which being formed by processing a single piece of sheet metal, it is possible to reduce the heat capacity and weight of the turbine housing. Further, since they are each formed by processing a single piece of sheet metal, the manufacture of the scroll part 2 and the connection part 4 is facilitated.
Further, as described above, since a turbine housing is broken down into modules such as the scroll part 2 inside which an exhaust gas flow path 2A of a spiral shape is formed and the connection part 4 connectable to a bearing housing, the scroll part 2 and the connection part 4 being connected to each other via the annular lid part 6, it is possible to configure the turbine housing assembly 1 of the present invention as an assembly of a plurality of standardized constituent modules. Thus, it is possible to facilitate the manufacture. Moreover, since the scroll part 2 and the connection part 4 are connected to each other by welding, the sealability is enhanced and thus the conventional outer shell is no longer required. As a result, it is possible to reduce the weight and heat capacity of the turbine housing.
Still further, as described above, since the turbine housing is broken down into modules such as the scroll part 2 and the connection part 4, which are connected to each other in the turbine axial direction via the annular lid part 6 that is orthogonal to the turbine axial direction line 7, it is possible to block the influence of the exhaust gas having a high temperature in the scroll part 2 by the annular lid part 6. Thus, it is possible to form the connection part 4 of a stainless material having lower heat resistance than that of the scroll part 2. That is, it is possible to form the connection part 4 of a less expensive stainless material containing less nickel than the scroll part 2. As a result, it is possible to reduce the cost of the turbine housing compared to the case where a whole turbine housing is formed of a single material.
Also, as described above, with the annular lid part 6 having a separate body separate from the scroll part 2 and the connection part 4, it is possible to form each constituent member such as the scroll part 2, the connection part 4, and the annular lid part 6 into a simple shape. As a result, it is possible to facilitate the manufacture of each constituent member. Further, at this time, forming the annular lid part 6 by processing a single piece of sheet metal also contributes to reducing the weight and heat capacity of a turbine housing.
Still further, as described above, the turbine housing assembly 1 of the present invention further includes the exhaust part 8 of a tubular shape having a separate body separate from the scroll part 2, and the exhaust part 8 is connected to the scroll part 2 in the turbine axial direction so that the exhaust part 8 is in communication with the exhaust gas outlet 2B. By breaking down a turbine housing into modules such as the scroll part 2, the connection part 4, and the exhaust part 8 of a tubular shape, the exhaust part 8 of a tubular shape being configured to have a separate body separate from the scroll part 2, it is possible to form each constituent member included in the turbine housing assembly 1 of the present invention into a simple shape. As a result, manufacture of each constituent member is facilitated. Further, since the exhaust part 8 is connected to the scroll part 2 in the turbine axial direction, the constituent members such as the connection part 4, the annular lid part 6, the scroll part 2 and the exhaust part 8 are all connected in the turbine axial direction. As a result, assembling property of the turbine housing assembly 1 is enhanced.
Still further, as described above, since the turbine housing is broken down into modules such as the scroll part 2 and the exhaust part 8, the exhaust part 8 being brought into communication with the exhaust gas outlet 2B of the scroll part 2 in a state where the gap “a” is formed between the outer circumferential face of the exhaust part 8 and the projecting portion 22a of the scroll part 2, it becomes difficult for the exhaust gas having a high temperature and flowing through the exhaust gas flow path 2A of the scroll part 2 to affect the exhaust part 8. Thus, it is possible to form the exhaust part 8 of a material having lower heat resistance than that of the scroll part 2. Specifically, it is possible to form the exhaust part 8 of a less expensive stainless material containing less nickel than the scroll part 2. As a result, it is possible to reduce the cost.
The turbine housing assembly 1 of the present invention including a plurality of constituent members such as the scroll part 2, the connection part 4, the annular lid part 6 and the exhaust part 8 is manufactured as described below.
First, the scroll part 2, the connection part 4, and the annular lid part 6 are each formed by processing a single piece of sheet metal (scroll part forming step, connection part forming step, and annular lid part forming step), and then the exhaust part 8, the engine-side flange portion 10, the muffler-side flange portion 12, etc are prepared.
Next, as illustrated in
Further, as illustrated in
Still further, as illustrated in
Finally, as illustrated in
Here, the technique for: connecting the end portion 8a of the exhaust part 8 to the scroll part 2; connecting the positioning portions 6b on the other side of the annular lid part 6 to the end faces of the threaded bushings 16; connecting the exhaust gas inlet 24 of the scroll part 2 to the engine-side flange portion 10; and connecting the other end portion 8b of the exhaust part 8 to the muffler-side flange portion 12, is not limited to welding. For example, the connection may be performed by fastening bolts, brazing, or the like.
According to the manufacturing method of the turbine housing assembly with the above configuration, since a turbine housing is broken down into modules such as the scroll part 2 inside which the exhaust gas flow path 2A of a spiral shape is formed and the connection part 4 connectable to a bearing housing, the scroll part 2 and the connection part 4 being connected to each other via the annular lid part 6, it is possible to manufacture the turbine housing assembly 1 only by connecting the scroll part 2 and the connection part 4 that have been separately manufactured. Thus, the manufacture is facilitated.
Further, since the annular lid part 6 has a separate body separate from the scroll part 2 and the connection part 4, it is possible to form each constituent member such as the scroll part 2, the connection part 4, and the annular lid part 6 into a simple shape. As a result, the manufacture of each constituent member is facilitated.
Still further, as described above, the exhaust part 8 of a tubular shape having a separate body separate from the scroll part 2 is prepared and connected to the scroll part 2 in the turbine axial direction so that the exhaust part 8 communicates with the exhaust gas outlet 2B of the scroll part 2 (connection step). Thus, the constituent members such as the connection part 4, the annular lid part 6, the scroll part 2, and the exhaust part 8 are all connected in the turbine axial direction. As a result, assembling property of the turbine housing assembly 1 is improved.
According to the present invention, it is possible to provide a turbine housing assembly in which reduction of weight, cost-cutting, facilitation of manufacture, reduction of heat capacity are even more promoted compared to a conventional turbine housing made of sheet metal, and a manufacturing method of the turbine housing assembly.
Embodiments of the present invention were described in detail above, but the present invention is not limited thereto, and various amendments and modifications may be implemented within a scope that does not depart from the present invention.
For instance,
The present invention can be suitably used as a turbine housing assembly for a turbocharger, preferably a turbine housing assembly for a VG turbocharger for a vehicle, and as a manufacturing method of the turbine housing assembly.
Jinnai, Yasuaki, Arimizu, Hiroyuki, Kramer, Koen
Patent | Priority | Assignee | Title |
11732729, | Jan 26 2021 | JPMORGAN CHASE BANK, N A , AS ADMINISTRATIVE AGENT | Sheet metal turbine housing |
11821361, | Jul 06 2022 | Pratt & Whitney Canada Corp. | Gas turbine intake for aircraft engine and method of inspection thereof |
11851202, | Jun 23 2022 | Pratt & Whitney Canada Corp.; Pratt & Whitney Canada Corp | Aircraft engine, gas turbine intake therefore, and method of guiding exhaust gasses |
11891947, | Jun 23 2022 | Pratt & Whitney Canada Corp. | Aircraft engine, gas turbine intake therefore, and method of guiding exhaust gasses |
Patent | Priority | Assignee | Title |
4850797, | Jan 21 1988 | Double chambered turbine housing and seal | |
6553762, | Dec 12 2000 | Daimler AG | Exhaust gas turbocharger for an internal combustion engine |
7198459, | Nov 13 2003 | Benteler Automobiltechnik GmbH; Borgwarner Inc. | Casing arrangement for a turbocharger of an internal combustion engine |
7371047, | Apr 28 2004 | Daimler AG | Exhaust gas turbine for an exhaust gas turbocharger |
20060133931, | |||
20110280717, | |||
CN102127674, | |||
CN102203396, | |||
CN1508435, | |||
DE102004039477, | |||
EP1357278, | |||
JP2006527322, | |||
JP2007224827, | |||
JP200857448, | |||
JP2011174460, | |||
JP61132800, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 22 2013 | Mitsubishi Heavy Industries, Ltd. | (assignment on the face of the patent) | / | |||
Oct 20 2014 | JINNAI, YASUAKI | MITSUBISHI HEAVY INDUSTRIES, LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 034043 | /0361 | |
Oct 20 2014 | ARIMIZU, HIROYUKI | MITSUBISHI HEAVY INDUSTRIES, LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 034043 | /0361 | |
Oct 20 2014 | KRAMER, KOEN | MITSUBISHI HEAVY INDUSTRIES, LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 034043 | /0361 | |
Jul 01 2016 | MITSUBISHI HEAVY INDUSTRIES, LTD | MITSUBISHI HEAVY INDUSTRIES ENGINE & TURBOCHARGER, LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051732 | /0494 | |
Jan 01 2019 | MITSUBISHI HEAVY INDUSTRIES, LTD | MITSUBISHI HEAVY INDUSTRIES, LTD | CHANGE OF ADDRESS | 051732 | /0489 |
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